1 | module clip
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2 | #(
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3 | parameter shift = 24, // right shift of the result
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4 | parameter width = 27, // bit width of the input data
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5 | parameter widthr = 12 // bit width of the output data
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6 | )
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7 | (
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8 | input wire clock, frame, reset,
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9 | input wire [4*6-1:0] del_data,
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10 | input wire [4*6-1:0] amp_data,
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11 | input wire [4*16-1:0] tau_data,
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12 | input wire [4*width-1:0] inp_data,
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13 | output wire [4*widthr-1:0] out_data
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14 | );
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15 |
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16 | localparam width1 = width + 16;
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17 | localparam width2 = width + 6;
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18 | localparam width3 = width1 + 2;
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19 |
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20 | reg int_wren_reg, int_wren_next;
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21 | reg int_flag_reg, int_flag_next;
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22 | reg [1:0] int_chan_reg, int_chan_next;
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23 | reg [2:0] int_case_reg, int_case_next;
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24 | reg [7:0] int_addr_reg, int_addr_next;
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25 |
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26 | reg [5:0] del_addr_reg, del_addr_next;
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27 | wire [5:0] del_addr_wire;
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28 | wire [7:0] int_addr_wire;
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29 |
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30 | reg [widthr-1:0] out_data_reg [4:0], out_data_next [4:0];
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31 | wire [widthr-1:0] out_data_wire;
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32 |
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33 | wire [width3-1:0] add_data_wire;
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34 |
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35 | wire [width1-1:0] mul_data_wire1;
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36 | wire [width2-1:0] mul_data_wire2;
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37 |
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38 | reg [width-1:0] inp_data_reg [3:0], inp_data_next [3:0];
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39 | wire [width-1:0] inp_data_wire [4:0];
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40 |
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41 | reg [5:0] amp_data_reg, amp_data_next;
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42 | wire [5:0] amp_data_wire [3:0];
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43 |
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44 | reg [15:0] tau_data_reg, tau_data_next;
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45 | wire [15:0] tau_data_wire [3:0];
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46 |
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47 | integer i;
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48 | genvar j;
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49 |
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50 | generate
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51 | for (j = 0; j < 4; j = j + 1)
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52 | begin : INT_DATA
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53 | assign inp_data_wire[j] = inp_data[j*width+width-1:j*width];
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54 | assign amp_data_wire[j] = amp_data[j*6+6-1:j*6];
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55 | assign tau_data_wire[j] = tau_data[j*16+16-1:j*16];
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56 | end
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57 | endgenerate
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58 |
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59 | lpm_mux #(
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60 | .lpm_size(4),
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61 | .lpm_type("LPM_MUX"),
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62 | .lpm_width(8),
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63 | .lpm_widths(2)) mux_unit_1 (
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64 | .sel(int_chan_next),
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65 | .data({
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66 | 2'd3, del_data[3*6+6-1:3*6],
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67 | 2'd2, del_data[2*6+6-1:2*6],
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68 | 2'd1, del_data[1*6+6-1:1*6],
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69 | 2'd0, del_data[0*6+6-1:0*6]}),
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70 | .result(int_addr_wire));
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71 |
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72 | assign del_addr_wire = del_addr_reg - int_addr_wire[5:0];
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73 |
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74 | lpm_mult #(
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75 | .lpm_hint("MAXIMIZE_SPEED=9"),
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76 | .lpm_representation("UNSIGNED"),
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77 | .lpm_type("LPM_MULT"),
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78 | .lpm_pipeline(3),
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79 | .lpm_widtha(width),
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80 | .lpm_widthb(16),
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81 | .lpm_widthp(width1)) mult_unit_1 (
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82 | .clock(clock),
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83 | .clken(int_wren_reg),
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84 | .dataa(inp_data_wire[4]),
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85 | .datab(tau_data_reg),
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86 | .result(mul_data_wire1));
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87 |
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88 | lpm_mult #(
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89 | .lpm_hint("MAXIMIZE_SPEED=9"),
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90 | .lpm_representation("UNSIGNED"),
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91 | .lpm_type("LPM_MULT"),
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92 | .lpm_pipeline(3),
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93 | .lpm_widtha(width),
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94 | .lpm_widthb(6),
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95 | .lpm_widthp(width2)) mult_unit_2 (
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96 | .clock(clock),
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97 | .clken(int_wren_reg),
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98 | .dataa(inp_data_reg[0]),
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99 | .datab(amp_data_reg),
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100 | .result(mul_data_wire2));
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101 |
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102 | assign add_data_wire =
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103 | {2'b0, mul_data_wire2, {(width1-width2){1'b0}}}
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104 | - {2'b0, mul_data_wire1};
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105 |
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106 | assign out_data_wire = add_data_wire[width3-1] ? {(widthr){1'b0}} :
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107 | add_data_wire[shift+widthr-1:shift]
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108 | + {{(widthr-1){add_data_wire[width3-1]}}, add_data_wire[shift-1]};
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109 |
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110 |
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111 | altsyncram #(
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112 | .address_aclr_b("NONE"),
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113 | .address_reg_b("CLOCK0"),
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114 | .clock_enable_input_a("BYPASS"),
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115 | .clock_enable_input_b("BYPASS"),
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116 | .clock_enable_output_b("BYPASS"),
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117 | .intended_device_family("Cyclone III"),
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118 | .lpm_type("altsyncram"),
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119 | .numwords_a(256),
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120 | .numwords_b(256),
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121 | .operation_mode("DUAL_PORT"),
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122 | .outdata_aclr_b("NONE"),
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123 | .outdata_reg_b("CLOCK0"),
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124 | .power_up_uninitialized("FALSE"),
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125 | .read_during_write_mode_mixed_ports("DONT_CARE"),
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126 | .widthad_a(8),
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127 | .widthad_b(8),
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128 | .width_a(width),
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129 | .width_b(width),
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130 | .width_byteena_a(1)) ram_unit_1 (
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131 | .wren_a(int_wren_reg),
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132 | .clock0(clock),
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133 | .address_a(int_addr_reg),
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134 | .address_b({int_addr_wire[7:6], del_addr_wire}),
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135 | .data_a(inp_data_reg[0]),
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136 | .q_b(inp_data_wire[4]),
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137 | .aclr0(1'b0),
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138 | .aclr1(1'b0),
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139 | .addressstall_a(1'b0),
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140 | .addressstall_b(1'b0),
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141 | .byteena_a(1'b1),
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142 | .byteena_b(1'b1),
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143 | .clock1(1'b1),
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144 | .clocken0(1'b1),
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145 | .clocken1(1'b1),
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146 | .clocken2(1'b1),
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147 | .clocken3(1'b1),
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148 | .data_b({(width){1'b1}}),
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149 | .eccstatus(),
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150 | .q_a(),
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151 | .rden_a(1'b1),
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152 | .rden_b(1'b1),
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153 | .wren_b(1'b0));
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154 |
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155 | always @(posedge clock)
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156 | begin
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157 | if (reset)
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158 | begin
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159 | int_wren_reg <= 1'b1;
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160 | int_flag_reg <= 1'b0;
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161 | int_chan_reg <= 2'd0;
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162 | int_case_reg <= 3'd0;
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163 | del_addr_reg <= 6'd0;
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164 | int_addr_reg <= 8'd0;
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165 | amp_data_reg <= 6'd0;
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166 | tau_data_reg <= 16'd0;
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167 | for(i = 0; i <= 3; i = i + 1)
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168 | begin
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169 | inp_data_reg[i] <= {(width){1'b0}};
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170 | end
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171 | for(i = 0; i <= 4; i = i + 1)
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172 | begin
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173 | out_data_reg[i] <= {(widthr){1'b0}};
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174 | end
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175 | end
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176 | else
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177 | begin
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178 | int_wren_reg <= int_wren_next;
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179 | int_flag_reg <= int_flag_next;
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180 | int_chan_reg <= int_chan_next;
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181 | int_case_reg <= int_case_next;
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182 | del_addr_reg <= del_addr_next;
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183 | int_addr_reg <= int_addr_next;
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184 | amp_data_reg <= amp_data_next;
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185 | tau_data_reg <= tau_data_next;
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186 | for(i = 0; i <= 3; i = i + 1)
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187 | begin
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188 | inp_data_reg[i] <= inp_data_next[i];
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189 | end
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190 | for(i = 0; i <= 4; i = i + 1)
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191 | begin
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192 | out_data_reg[i] <= out_data_next[i];
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193 | end
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194 | end
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195 | end
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196 |
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197 | always @*
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198 | begin
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199 | int_wren_next = int_wren_reg;
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200 | int_flag_next = int_flag_reg;
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201 | int_chan_next = int_chan_reg;
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202 | int_case_next = int_case_reg;
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203 | del_addr_next = del_addr_reg;
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204 | int_addr_next = int_addr_reg;
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205 | amp_data_next = amp_data_reg;
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206 | tau_data_next = tau_data_reg;
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207 | for(i = 0; i <= 3; i = i + 1)
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208 | begin
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209 | inp_data_next[i] = inp_data_reg[i];
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210 | end
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211 | for(i = 0; i <= 4; i = i + 1)
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212 | begin
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213 | out_data_next[i] = out_data_reg[i];
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214 | end
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215 |
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216 | case (int_case_reg)
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217 | 0:
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218 | begin
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219 | // write zeros
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220 | int_wren_next = 1'b1;
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221 | del_addr_next = 6'd0;
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222 | int_addr_next = 8'd0;
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223 | amp_data_next = 6'd0;
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224 | tau_data_next = 16'd0;
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225 | for(i = 0; i <= 3; i = i + 1)
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226 | begin
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227 | inp_data_next[i] = {(width){1'b0}};
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228 | end
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229 | for(i = 0; i <= 4; i = i + 1)
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230 | begin
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231 | out_data_next[i] = {(widthr){1'b0}};
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232 | end
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233 |
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234 | int_case_next = 3'd1;
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235 | end
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236 | 1:
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237 | begin
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238 | // write zeros
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239 | int_addr_next = int_addr_reg + 8'd1;
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240 | if (&int_addr_reg)
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241 | begin
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242 | int_wren_next = 1'b0;
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243 | int_flag_next = 1'b0;
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244 | int_chan_next = 2'd0;
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245 | int_case_next = 3'd2;
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246 | end
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247 | end
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248 | 2: // frame
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249 | begin
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250 | int_flag_next = 1'b0;
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251 | int_wren_next = frame;
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252 | if (frame)
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253 | begin
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254 | int_addr_next[7:6] = 2'd0;
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255 |
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256 | // set read addr for 2nd pipeline
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257 | int_chan_next = 2'd1;
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258 |
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259 | // register input data for 2nd, 3rd and 4th sums
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260 | inp_data_next[1] = inp_data_wire[1];
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261 | inp_data_next[2] = inp_data_wire[2];
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262 | inp_data_next[3] = inp_data_wire[3];
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263 |
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264 | // prepare registers for 1st sum
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265 | inp_data_next[0] = inp_data_wire[0];
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266 |
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267 | tau_data_next = tau_data_wire[0];
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268 | amp_data_next = amp_data_wire[0];
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269 |
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270 | int_case_next = 3'd3;
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271 | end
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272 | if (int_flag_reg) // register 4th sum
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273 | begin
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274 | int_addr_next[5:0] = del_addr_reg;
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275 | // register 1st product
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276 | out_data_next[0] = out_data_wire;
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277 | end
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278 | end
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279 | 3: // 1st sum
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280 | begin
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281 | int_addr_next[7:6] = 2'd1;
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282 |
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283 | // set read addr for 3rd pipeline
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284 | int_chan_next = 2'd2;
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285 |
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286 | // prepare registers for 2nd sum
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287 | inp_data_next[0] = inp_data_reg[1];
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288 |
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289 | tau_data_next = tau_data_wire[1];
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290 | amp_data_next = amp_data_wire[1];
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291 |
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292 | // register 2nd product
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293 | out_data_next[1] = out_data_wire;
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294 |
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295 | int_case_next = 3'd4;
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296 | end
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297 | 4: // 2nd sum
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298 | begin
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299 | int_addr_next[7:6] = 2'd2;
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300 |
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301 | // set read addr for 4th pipeline
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302 | int_chan_next = 2'd3;
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303 |
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304 | // prepare registers for 3rd sum
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305 | inp_data_next[0] = inp_data_reg[2];
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306 |
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307 | tau_data_next = tau_data_wire[2];
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308 | amp_data_next = amp_data_wire[2];
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309 |
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310 | // register 3rd product
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311 | out_data_next[2] = out_data_wire;
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312 |
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313 | del_addr_next = del_addr_reg + 6'd1;
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314 |
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315 | int_case_next = 3'd5;
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316 | end
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317 | 5: // 3rd sum
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318 | begin
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319 | int_flag_next = 1'b1;
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320 |
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321 | int_addr_next[7:6] = 2'd3;
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322 |
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323 | // set read addr for 1st pipeline
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324 | int_chan_next = 2'd0;
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325 |
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326 | // prepare registers for 4th sum
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327 | inp_data_next[0] = inp_data_reg[3];
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328 |
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329 | tau_data_next = tau_data_wire[3];
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330 | amp_data_next = amp_data_wire[3];
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331 |
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332 | // register 4th product
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333 | out_data_next[3] = out_data_wire;
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334 |
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335 | // register 4th output
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336 | out_data_next[4] = out_data_reg[0];
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337 |
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338 | int_case_next = 3'd2;
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339 | end
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340 | default:
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341 | begin
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342 | int_case_next = 3'd0;
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343 | end
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344 | endcase
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345 | end
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346 |
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347 | assign out_data = {out_data_reg[3], out_data_reg[2], out_data_reg[1], out_data_reg[4]};
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348 |
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349 | endmodule
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